SPEAKER:
Elette Boyle
TITLE:
Extractability Obfuscation
Abstract:
We initiate the study of extractability obfuscation, a notion first
suggested by Barak et al. (JACM 2012): An extractability obfuscator eO for
a class of algorithms M guarantees that if an efficient attacker A can
distinguish between obfuscations eO(M_1), eO(M_2) of two algorithms
M_1,M_2 in M, then A can efficiently recover (given M_1 and M_2) an
input on which M_1 and M_2 provide different outputs.
- We rely on the recent candidate virtual black-box obfuscation constructions
to provide candidate constructions of extractability obfuscators for NC^1; next,
following the blueprint of Garg et al. (FOCS 2013), we show how to bootstrap
the obfuscator for NC^1 to an obfuscator for all non-uniform polynomial-time
Turing machines. In contrast to the construction of Garg et al., which relies
on indistinguishability obfuscation for NC^1, our construction enables succinctly
obfuscating non-uniform Turing machines (as opposed to circuits), without
turning running-time into description size.
- We introduce a new notion of functional witness encryption, which
enables encrypting a message m with respect to an instance x, language L,
and function f, such that anyone (and only those) who holds a witness w
for x \in L can compute f(m,w) on the message and particular known witness.
We show that functional witness encryption is, in fact, equivalent to
extractability obfuscation.
- We demonstrate other applications of extractability extraction, including
the first construction of fully (adaptive-message) indistinguishability-secure
functional encryption for an unbounded number of key queries and unbounded message
spaces.
- We finally relate indistinguishability obfuscation and extractability
obfuscation and show special cases when indistinguishability obfuscation
can be turned into extractability obfuscation.
Joint work with Kai-Min Chung and Rafael Pass.